Comorbidity in chronic obstructive pulmonary disease. Related to disease severity?

Abstract

Background and objective

Several diseases commonly co-exist with chronic obstructive pulmonary disease (COPD), especially in elderly patients. This study aimed to investigate whether there is an association between COPD severity and the frequency of comorbidities in stable COPD patients.

Patients and methods

In this multicenter, cross-sectional study, patients with spirometric diagnosis of COPD attended to by internal medicine departments throughout Spain were consecutively recruited by 225 internal medicine specialists. The severity of airflow obstruction was graded using the Global Initiative for Chronic Obstructive Lung Disease (GOLD) and data on demographics, smoking history, comorbidities, and dyspnea were collected. The Charlson comorbidity score was calculated.

Results

Eight hundred and sixty-six patients were analyzed: male 93%, mean age 69.8 (standard deviation [SD] 9.7) years and forced vital capacity in 1 second 42.1 (SD 17.7)%. Even, the mean (SD) Charlson score was 2.2 (2.2) for stage I, 2.3 (1.5) for stage II, 2.5 (1.6) for stage III, and 2.7 (1.8) for stage IV (P=0.013 between stage I and IV groups), independent predictors of Charlson score in the multivariate analysis were age, smoking history (pack-years), the hemoglobin level, and dyspnea, but not GOLD stage.

Conclusion

COPD patients attended to in internal medicine departments show high scores of comorbidity. However, GOLD stage was not an independent predictor of comorbidity.

Keywords:

• Charlson
• comorbidity
• COPD

Introduction

Chronic obstructive pulmonary disease (COPD) is characterized by an abnormal inflammatory response of the lungs to noxious particles or gases.¹ In recent years, increasing attention has been paid to “systemic inflammation” that is often associated with COPD.^2–5 At the same time there has been a growing recognition that comorbidities such as cardiovascular disease,^6–8 metabolic syndrome,⁹ cachexia,¹⁰ anemia,¹¹ osteoporosis,¹² or depression¹³ may be present in a greater proportion of patients with COPD than in the general population.^14–16 Comorbidities have been reported to have a negative impact on prognosis and survival.^17–19 A publication describes a systemic phenotype in patients with milder airway obstruction, but higher proportion of obesity, cardiovascular disorders, diabetes mellitus, and systemic inflammation.²⁰ This group had more admissions due to cardiovascular disease (hazard ratio [HR] 2.87, P=0.01).

Cigarette smoking is a common risk factor for some of these comorbidities. However, it has been found that, independently of exposure, for every 10% decrease in forced vital capacity in 1 second (FEV₁), overall mortality increased 14%, cardiovascular mortality by 28%, and coronary complications by at least 20%.²¹ These findings would suggest that COPD airflow severity could be related to the presence of comorbidities.

Many of the studies of comorbidity in patients with COPD come from population databases^6,18 or cohorts from respiratory medicine departments,^22–24 even though patients with COPD and other comorbid conditions are currently attended to by other departments such as internal medicine²⁵ or cardiology.²⁶ Indeed, the fact that patients are attended to by the respiratory medicine department rather than referred to other departments may actually select patients with less severe comorbid conditions.²⁷

In the ECLIPSE study, the comorbidities were more prevalent in COPD patients than in controls and occurred to the same extent irrespective of the Global Initiative for Chronic Obstructive Lung Disease (GOLD) stage,¹⁵ and the comorbidities worsened the prognosis and increased the mortality.¹⁶ The patients were recruited from respiratory medicine departments and evaluation of comorbidities was not the main objective of the study.

We hypothesized that there is an association between COPD airflow severity and comorbidity, in such a way that to major COPD airflow limitation, major prevalence of comorbidity.

The aims of this study were: 1) to determine the prevalence of comorbid conditions in a large cohort of outpatients with COPD attended to by internal medicine departments, and 2) to investigate whether the comorbidity is related to disease severity.

Patients and methods

In this observational, cross-sectional multicenter study, patients were enrolled consecutively by 225 internal medicine specialists throughout Spain in an outpatient setting. Patients with COPD diagnosed by spirometry at least 6 months earlier were eligible for inclusion. Subjects must have a smoking history of ≥10 pack-years. Each specialist aimed to enroll five outpatients with a distribution of COPD severity according to the degree of airflow obstruction by GOLD criteria¹ as follows: one patient with stage I (mild) disease (FEV₁ ≥80%) or stage II (moderate) disease (50%≤ FEV₁ <80%), two patients with stage III (severe) disease (30%≤ FEV₁ <50%), and two patients with stage IV (very severe) disease (FEV₁ <30% or FEV₁ <50% with chronic respiratory failure). This distribution was selected to help ensure compliance with the sample size calculation (see below).

All patients were free from an exacerbation of COPD requiring treatment with corticosteroids or antibiotics in the 4 weeks prior to inclusion.

Strict confidentiality was maintained and all data were analyzed anonymously. All patients signed an informed consent, which included permission to use the data collected to be used in the study. The relevant ethics committee approved the study.

Variables

For eligible patients, demographic data including smoking habit and data on COPD were collected. Comorbidities were recorded in two different ways, as a predetermined list of 24 diseases (Supplementary material) and as a predefined list of diseases used to calculate the Charlson index (both unadjusted and age-adjusted).²⁵ We considered Charlson score of 0–1 as absence of comorbidity, 2 as low comorbidity and ≥3 as high comorbidity. Anemia was defined as hemoglobin under 13 g/dL in men and 12 g/dL in women. In addition, dyspnea was assessed using the Medical Research Council dyspnea scale. All COPD treatment and other concomitant medications were recorded.

Sample size

For comparison of GOLD stage I/II with stage I V, a difference on the Charlson scale of two points was considered relevant. For comparison of stage III and stage IV disease, a one point difference was considered relevant. This would require 200 patients with stage I or II disease, 400 with stage III disease, and 400 with stage IV disease to give mutually exclusive two-sided 95% confidence intervals (CIs) for these levels with an error of precision less than 0.3.

Statistical analysis

Descriptive statistics were calculated for all variables. For comparison of independent data between more than two groups (four COPD stages or between different smoking habits), an analysis of variance (ANOVA) was performed for quantitative variables and the Mantel–Haenszel test for qualitative ones. For comparison of independent data between two groups the Student’s t-test was used for quantitative variables and the χ² test for qualitative ones.

The association between study variables and the Charlson score was further examined by undertaking a multiple linear regression analysis. Study variables with a Pearson correlation coefficient with a Charlson score of greater than 0.1 were included as independent variables.

All statistical tests were two-tailed and significance was set at 5%. They were performed using the SAS statistical package, version 8.2 (SAS Institute Inc., Cary, NC, USA).

Results

Nine hundred and seventy-seven patients were included, but eventually 111 (11%) who did not meet the criteria of smoking more than ten packs per year, post bronchodilator FEV₁/FVC less than 70%, and present value of the Charlson index were excluded from the analysis. In total, 866 patients were included in the study.

The demographic characteristics of the patients included in the study are summarized in Table 1. There was a statistically significant greater proportion of men, older age, and greater cigarette consumption measured in pack-years with increasing disease severity. No differences were found in body mass index in the different groups of COPD severity. This was a population of patients with a relatively high hospitalization rate the preceding year, and this rate increased significantly with COPD severity.

Table 1 Demographic characteristics

GOLD stage	Stage I N=43	Stage II N=167	Stage III N=362	Stage IV N=294	Total N=866
Sexb male (%)	38 (88.4)	136 (81.4)	328 (90.6)	256 (87.1)	758 (87.5)
Age, years (SD)b	65.9 (10.2)	68.0 (10.9)	70.1 (9.4)	70.9 (9.01)	69.8 (9.7)
BMI, kg/m^2	28.0 (4.3)	27.0 (4.2)	28.0 (4.8)	27.0 (4.6)	27.5 (4.6)
Smoking statusb
Ex-smoker	29 (67.4%)	119 (71.3%)	287 (79.2%)	238 (80.9%)	673 (77.8%)
Smoker	14 (32.6%)	48 (28.7%)	75 (20.8%)	56 (19.1%)	193 (22.2%)
Pack-years (interquartile range)a,c	30.0 (22.5/45.0)	36.0 (20.0/51.0)	40.5 (28.4/60.0)	48.0 (31.3/67.5)	41.3 (30.0/60.0)
Dyspnea (MRC)c	1.0 (0.7)	1.2 (0.9)	2.3 (0.9)	3.2 (0.9)	2.3 (1.2)
FEV1, % predictedc	85.2 (5.7)	63.7 (8.7)	40.4 (5.9)	25.6 (4.1)	42.1 (17.7)
SaO2, %c	92.6 (4.0)	91.3 (7.3)	89.6 (6.6)	85.9 (8.8)	89.1 (7.8)
No of days in hospital for any cause during previous 12 months (interquartile range)a,b	8.0 (7.0/16.0)	12.0 (8.0/24.0)	12.5 (8.0/26.0)	20.0 (10.0/37.0)	15.0 (8.0/29.0)

Notes: Quantitative data presented as mean (SD) unless otherwise stated.

a Median (interquartile range)

b Significant group differences (P<0.05)

c Significant group differences (P<0.001).

Abbreviations: BMI, body mass index; FEV₁, forced vital capacity in 1 second; GOlD, Global Initiative for Chronic Obstructive Lung Disease; MRC, Medical Research Council; SD, standard deviation.

Univariate analysis

The mean (standard deviation) unadjusted and age-adjusted Charlson score was 2.5 (1.7) and 5.0 (2.0), respectively, for the overall sample. The score increased significantly with increasing disease severity (Table 2). Charlson scores were significantly different on analysis by the presence or absence of respiratory failure (SaO₂ <90%) (2.7 [1.8] versus 2.4 [1.6], P=0.003).

Table 2 Charlson index according to COPD severity

	Stage I N=43	Stage II N=167	Stage III N=362	Stage IV N=294	Total N=866
Charlson scorea	2.2 (2.2)	2.3 (1.5)	2.5 (1.6)	2.7 (1.8)	2.5 (1.7)
Comorbidity according to Charlson score
No (score ≤1)a	21 (46.5%)	74 (44.4%)	115 (31.8%)	93 (31.5%)	303 (35.0%)
Mild (score =2)	14 (34.9%)	40 (23.9%)	107 (30.1%)	66 (22.5%)	227 (26.2%)
High (score ≥3)a	8 (18.6%)	53 (31.7%)	140 (38.1%)	135 (46%)	336 (38.8%)

Note:

a Significant group differences (P<0.05) according to Mantel–Haenszel test.

Abbreviation: COPD, chronic obstructive pulmonary disease.

The most common comorbidity across all groups of COPD severity was arterial hypertension (57.1% of the sample) followed by hypercholesterolemia (33.3%) and diabetes mellitus (31.1%). An overview of the most frequently reported metabolic and cardiovascular comorbidities is given in Table 3. Conditions that show an association with COPD airflow limitation severity were hypercholesterolemia, diabetes mellitus, heart failure, and atrial fibrillation.

Table 3 Metabolic and cardiovascular comorbidities according to COPD severity

Disease	Stage I N=43	Stage II N=167	Stage III N=362	Stage IV N=294	Total N=866
Hypertension	34 (79.1%)	90 (53.9%)	200 (55.2%)	171 (58.2%)	495 (57.1%)
Hypercholesterolemiaa	24 (55.8%)	63 (37.7%)	111 (30.6%)	90 (30.6%)	288 (33.2%)
Diabetesa	6 (13.9%)	42 (25.1%)	122 (33.7%)	100 (34.0%)	270 (31.2%)
Heart failurea	5 (11.6%)	22 (13.2%)	86 (23.7%)	86 (29.2%)	199 (23.0%)
Atrial fibrillationa	2 (4.6%)	22 (13.2%)	68 (18.7%)	73 (24.8%)	165 (19.0%)
Peripheral vascular disease	6 (13.9%)	22 (13.2%)	68 (18.8%)	54 (18.3%)	150 (17.3%)
Ischemic heart disease	10 (23.3%)	17 (10.2%)	68 (18.8%)	47 (15.9)	142 (16.4%)

Note:

a Significant group differences (P<0.05) according to Mantel–Haenszel test.

Abbreviation: COPD, chronic obstructive pulmonary disease.

Other frequently reported comorbidities like cataracts (21.1% of the sample), arthrosis (19.3%), anxiety (14.3%), and depression (11.1%) did not show an association with COPD severity.

Obstructive sleep apnea was reported in 10.6% of the overall sample, with no significant differences according to GOLD stage: (P=0.64): 5% in GOLD I, 11.7% in GOLD II, 10.9% in GOLD III, and 9.8% in GOLD I V.

Anemia was reported in 26% of the overall sample but no significant association was found between COPD severity and presence of anemia (P=0.07). However, anemia was more prevalent in patients with greater comorbidity as measured by the Charlson index (P<0.001) (Table 4). When patients with renal failure, digestive disease, hepatic disease and cancer were excluded, the prevalence was 21.6%.

Table 4 Anemia according to Charlson index (ChI)

Anemia	No comorbidity: ChI ≤1	Lowcomorbidity: ChI =2	High comorbidity: ChI ≥3	P-value
n	282	221	334
No	247 (87.5%)	169 (76.4%)	203 (60.7%)	<0.001
Yes	35 (12.5%)	52 (23.6%)	131 (39.2%)

Cancer was reported in 92/866 patients (10.6%) in the overall sample, with no significant differences according to GOLD stage. The body system most frequently affected was the respiratory system, accounting for 17 of the 92 patients with malignancies (18.5%). All 17 of these patients with lung cancer belonged to GOLD stage III or I V.

Pneumonia in the previous 12 months increased significantly according to GOLD stage (P=0.02): 7% in GOLD I, 7.8% in GOLD II, 11.6% in GOLD III, and 17.0% in GOLD I V. These effects were also observed when excluding the patients who were receiving regular treatment with inhaled corticosteroids (P<0.001): 5% in GOLD I, 5.6% in GOLD II, 11.6% in GOLD III, and 18.6% in GOLD IV.

Multivariate analysis

To clarify whether severity of airflow obstruction (measured by GOLD stage) and comorbidity (measured by the Charlson index) were independently related, a multivariate regression analysis (Table 5) was performed. Variables with a Pearson correlation coefficient greater than ±0.1 that did not show multicollinearity (COPD severity, age, pack-years, hemoglobin levels, and presence of dyspnea according to the Medical Research Council definition) and the Charlson score as the dependent variable were included in the analysis. COPD severity was not significantly associated with Charlson score (P=0.13) although a significant association remained for age (P<0.001), pack-years (P=0.03), hemoglobin level (P<0.001), and dyspnea (P=0.04). The coefficient of determination (R2) was 0.11.

Table 5 Multiple linear regression analysis with the Charlson score as the dependent variable and including variables with a Pearson correlation coefficient greater than ±0.1

Variable	Parameter estimate	Standard error	t value	P-value.|t|
COPD severity	0.11329	0.07509	1.51	0.1318
Age	0.02922	0.00660	4.43	<0.0001
Pack-years	0.00519	0.00238	2.17	0.0300
Dyspnea	0.60459	0.29706	2.04	0.0422
Hemoglobin	−0.01746	0.00323	−5.41	<0.0001

Abbreviation: COPD, chronic obstructive pulmonary disease.

Discussion

In this study, we investigated the relationship between comorbidities and COPD airflow limitation severity as determined by GOLD staging in patients attended to consecutively as outpatients by internal medicine departments. We found that COPD patients frequently suffer from comorbid conditions although the frequency of these comorbidities according to Charlson index, were not directly related to COPD severity. Age, anemia, pack-years of smoking, and dyspnea were indeed independently associated with comorbidity.

Comparisons between epidemiological studies of comorbidities in COPD face a number of difficulties. For example, retrospective population studies of mortality from hospital records or death certificates may underestimate the contribution of COPD because it is not always recorded as a comorbid condition when it is present. To reduce underdiagnosis of comorbidities the data were collected from medical history and after a prospective interview with the patient. Likewise, a universal definition of COPD has not always been applied, although the use of GOLD criteria based on spirometry is now becoming widespread and is considered the “gold standard”.¹ An important aspect of our study was that only patients with COPD confirmed by spirometry were included in the sample. In addition, unlike previous studies, our study includes patients with all the stages of severity, from mild to very severe.

In a study investigating the value of the 6 minute walk distance for predicting mortality, Pinto-Plata et al²² recruited patients with COPD (mean FEV₁, 1.04 [0.39], comparable to stage III patients in our study) from pulmonary departments of two hospitals. The authors reported an age-adjusted Charlson score of 4.29 for patients who survived until the end of follow-up, and 4.14 and 4.19 for those who survived for one and two assessments, respectively. These values are somewhat lower than the ones reported in our study (5.0 [2.0] for patients with stage III disease). Another prospective study investigating the effect of sex on the clinical expression of COPD patients (mostly with stage II [47%] or stage III [45%] disease) seen in a pulmonary clinic reported an age-adjusted Charlson score of 4 for men and 2 for women,²³ whereas our mean age-adjusted Charlson scores were 5.1 (for men) and 4.6 (for women). In another study of mortality in COPD patients, Marti et al²⁴ retrospectively reviewed the records of patients receiving long-term oxygen therapy (mean age, 69 years; FEV₁, 25%). Even though comorbidity measured by the Charlson score was a predictor of all-cause mortality, the percentage of patients in that study with a Charlson score ≥2 was only 14% compared to 66% in our study.

Notwithstanding the difficulties of comparison, these studies would seem to suggest that in patients where the focus is on the respiratory aspect of their disease, the Charlson score is lower than when patients are treated by internal medicine specialists.

On the other hand, studies with prospective data collection are susceptible to selection bias. Clearly patients with stable disease recruited in a primary care day clinic are likely to be less ill than hospitalized patients suffering from a COPD exacerbation. Likewise, it might be expected that patients attended to by internal medicine departments would be more likely to suffer from comorbidities than those attended to by pulmonology departments.

For a meaningful discussion on selection biases resulting from patients attended to by pulmonology departments or internal medicine departments, data would be needed on the profile of patients admitted to one type of department or the other. The only study we could find on the subject was performed in 32 hospitals in Andalusia, Spain.²⁵ The investigators examined the hospital records of patients hospitalized for COPD exacerbations and found that 57% of the patients with a diagnosis of COPD were admitted to internal medicine departments, 31% to pulmonology departments, and 12% to other services. They found that women, older patients, patients with diabetes mellitus, heart failure, ischemic heart disease, and supraventricular arrhythmia were more likely to be admitted to internal medicine departments while active or former smokers, patients with pneumonia, and sleep disorders were more likely to be admitted to pulmonology departments. The study by San Román-Terán et al²⁵ would therefore suggest that, in the case of exacerbations at least, patients with prominent comorbidity are less likely to be admitted to pulmonology departments. The fact that the Charlson score in our study was higher than scores reported for samples drawn from pulmonology departments and the generally higher age of our patients would support this finding.

Agusti et al have recently published a study that came to the same conclusions than our work: comorbidities occurred to the same extent irrespective of the GOLD stage.¹⁵ In fact in our study, the univariate analysis Charlson score increased significantly with increasing disease severity (Table 2), but in the multivariate regression analysis, COPD severity was not significantly associated with Charlson score (Table 5). Both studies have important methodological differences between them. In our study unlike theirs, the measurement of comorbidities in relation to the severity of COPD was the main objective, comorbidities were recorded as a predetermined list of 24 diseases (Supplementary material) and as a predefined list of diseases used to calculate the Charlson index, participating investigators had full access to the patients’ medical records and patients were recruited from internal medicine departments. For example, in relation with this latest point, in Agusti’s study the prevalence of diabetes mellitus was 10% and heart failure 7%, versus 31% and 23% in ours.

On examination by individual comorbid conditions, arterial hypertension was found to be the most common comorbidity, followed by hypercholesterolemia and diabetes mellitus – all risk factors for heart disease. This would fit with a number of other studies that have underlined the high prevalence of concurrent cardiovascular disease and risk factors in patients with COPD, regardless of how the study sample was drawn.^{6–8,14,19,21,28} In our study, although arterial hypertension itself did not appear to be associated with more advanced disease, the prevalence of hypercholesterolemia, diabetes mellitus, heart failure, and atrial fibrillation were all associated with GOLD stage.

Another important comorbidity in patients with COPD is sleep apnea syndrome, because although its prevalence is similar as in the general population, the consequences are worse in patients with COPD. The prevalence of symptomatic sleep apnea syndrome in the general population is estimated at about 6%, but increases with age. In our sample, 10.6% of patients with COPD presented a syndrome of associated sleep apnea, and the frequency did not increase with the severity of COPD. This last point, as far as we know, has not been studied previously.^29,30

We found an increased risk of pneumonia according to COPD severity, and this effect was also seen in patients who have not been using inhaled corticosteroids. This is in line with a recently published study,³¹ which found an increased risk of hospitalization due to pneumonia in patients with GOLD stage II disease (HR: 2.25 [95% CI: 1.35–3.75]) and GOLD stage III–IV disease (HR: 5.65 [95% CI: 3.29–9.67]), and with a post hoc analysis of the TORCH study³² which found an increased risk of pneumonia in patients with FEV₁ <50% predicted.

Another point of particular interest is the fact that all patients with lung cancer had severe or very severe COPD. This supports the fact that the presence of COPD is a risk factor for lung cancer among smokers.³³

In any epidemiological study, it is very hard to determine cause and effect. There was a clear increase in the Charlson score with increasing disease severity. The differences between groups were significant, but when a multivariate analysis was undertaken with Charlson score as the dependent variable, COPD severity was not independently associated with Charlson score, whereas age, pack-years, hemoglobin, and dyspnea were. This would be consistent with the idea that while FEV₁ is important for staging the disease itself, other factors are significant for determining disease prognosis.³⁴

We used the Charlson index as most of the studies, up to now. A recent publication proposes a new index, the COPD specific comorbidity test (COTE), it was constructed based on the comorbidities that increase mortality risk using a multivariate analysis. It is another tool that helps assess mortality risk in patients with COPD.³⁵

This study has the limitation that the Charlson index quantifies the degree of comorbidity, but leaves out important comorbidities. Possibly the best approach would be individualized analysis, which is beyond the ambit of the study.

In conclusion, although the importance of comorbidities in COPD patients has been previously stressed in selected respiratory cohorts, we have found that, in a real-life population followed in an internal medicine out-patient clinic, these comorbidities are not directly determined by the severity of COPD, but by other independent prognostic factors such as pack-years, dyspnea, hemoglobin, and age. These findings, together with the variety of treatments associated with each comorbid condition, should be taken carefully into account when approaching the treatment of a COPD patient.

Supplementary material

Table

1. Cataract	13. Liver disease
2. Glaucoma	14. Arterial hypertension
3. Ischemic heart disease	15. Hypercholesterolemia
4. Heart failure	16. Diabetes mellitus
5. Atrial fibrillation	17. Fractures
6. Other arrhythmias	18. Osteoporosis
7. Stroke	19. Arthrosis
8. Dementia	20. Cancer
9. Peripheral vascular disease	21. Anxiety
10. Pneumonia	22. Depression
11. Sleep apnea syndrome	23. Kidney disease
12. Peptic ulcer disease	24. Anemia

Disclosure

The authors have no conflicts of interest to disclose in this work. This work was partially funded by Boehringer Ingelheim.